Plasmid cointegrates and their resolution mediated by transposon Tn3 mutants

Live tracking of a plant pathogen outbreak reveals rapid and successive, multidecade plasmid reduction

Quickly understanding the genomic changes that lead to pathogen emergence is necessary to launch mitigation efforts and reduce harm. In this study, we tracked in real time a 2022 bacterial plant disease outbreak in U.S. geraniums (Pelargonium × hortorum) caused by Xhp2022, a novel lineage of Xanthomonas hortorum. Genomes from 31 Xhp2022 isolates from seven states showed limited chromosomal variation and all contained a single plasmid (p93). Time tree and single nucleotide polymorphism whole-genome analysis estimated that Xhp2022 emerged within the last decade. The phylogenomic analysis determined that p93 resulted from the cointegration of three plasmids (p31, p45, and p66) found sporadically across isolates from previous outbreaks. Although p93 had a 49 kb nucleotide reduction, it retained putative fitness genes, which became predominant in the 2022 outbreak. Overall, we demonstrated, through rapid whole-genome sequencing and analysis, a recent, traceable event of genome reduction for niche adaptation typically observed over millennia in obligate and fastidious pathogens.IMPORTANCEThe geranium industry, valued at $4 million annually, faces an ongoing Xanthomonas hortorum pv. pelargonii (Xhp) pathogen outbreak. To track and describe the outbreak, we compared the genome structure across historical and globally distributed isolates. Our research revealed Xhp population has not had chromosome rearrangements since 1974 and has three distinct plasmids. In 2012, we found all three plasmids in individual Xhp isolates. However, in 2022, the three plasmids co-integrated into one plasmid named p93. p93 retained putative fitness genes but lost extraneous genomic material. Our findings show that the 2022 strain group of the bacterial plant pathogen Xanthomonas hortorum underwent a plasmid reduction. We also observed several Xanthomonas species from different years, hosts, and continents have similar plasmids to p93, possibly due to shared agricultural settings. We noticed parallels between genome efficiency and reduction that we see across millennia with obligate parasites with increased niche specificity.

Emerging patterns of plasmid-host coevolution that stabilize antibiotic resistance

Multidrug resistant bacterial pathogens have become a serious global human health threat, and conjugative plasmids are important drivers of the rapid spread of resistance to last-resort antibiotics. Whereas antibiotics have been shown to select for adaptation of resistance plasmids to their new bacterial hosts, or vice versa, a general evolutionary mechanism has not yet emerged. Here we conducted an experimental evolution study aimed at determining general patterns of plasmid-bacteria evolution. Specifically, we found that a large conjugative resistance plasmid follows the same evolutionary trajectories as its non-conjugative mini-replicon in the same and other species. Furthermore, within a single host-plasmid pair three distinct patterns of adaptive evolution led to increased plasmid persistence: i) mutations in the replication protein gene (trfA1); ii) the acquisition by the resistance plasmid of a transposon from a co-residing plasmid encoding a putative toxin-antitoxin system; iii) a mutation in the host's global transcriptional regulator gene fur. Since each of these evolutionary solutions individually have been shown to increase plasmid persistence in other plasmid-host pairs, our work points towards common mechanisms of plasmid stabilization. These could become the targets of future alternative drug therapies to slow down the spread of antibiotic resistance.

Relevance of hot spots in the evolution and transmission of Tn1546 in glycopeptide-resistant Enterococcus faecium (GREF) from broiler origin

OBJECTIVES

Glycopeptide-resistant enterococci are still present within the broiler sector, despite the EU ban of avoparcin more than a decade ago. In the present study, we have developed a rapid method for screening the flanking regions at the integration point of Tn1546 in glycopeptide-resistant Enterococcus faecium isolated from broiler farms.

METHODS

Total DNA was digested, ligated and amplified using primers from inside Tn1546. The resulting amplicons were purified and sequenced. Two new primers were designed based on obtained sequences.

RESULTS

Two main insertion points have been repeatedly found in isolates from the UK (n = 150). The first insertion point revealed that 25 isolates harboured Tn1546 positioned in a sequence with 96% homology to a streptomycin adenyltransferase gene (AY604739) from a Staphylococcus intermedius plasmid. At this insertion point, a direct repeat (GTCCT) was duplicated as previously described, indicating transposition at the target site. Furthermore, this 'hot spot' was also detected in isolates from Norway (2/8) and Denmark (17/20). The second insertion point detected in 45 isolates from the UK revealed integration into an Inc18-like plasmid, most likely by a process of target site recombination.

CONCLUSIONS

The presence of a common insertion point for isolates from different geographical areas could suggest the insertion of Tn1546 by transposition in a plasmid-specific site, followed by genetic rearrangement both inside the transposon and in the flanking regions.

Transposition of cyanobacterium insertion element ISY100 in Escherichia coli

The genome of the cyanobacterium Synechocystis sp. strain PCC6803 has nine kinds of insertion sequence (IS) elements, of which ISY100 in 22 copies is the most abundant. A typical ISY100 member is 947 bp long and has imperfect terminal inverted repeat sequences. It has an open reading frame encoding a 282-amino-acid protein that appears to have partial homology with the transposase encoded by a bacterial IS, IS630, indicating that ISY100 belongs to the IS630 family. To determine whether ISY100 has transposition ability, we constructed a plasmid carrying the IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible transposase gene at one site and mini-ISY100 with the chloramphenicol resistance gene, substituted for the transposase gene of ISY100, at another site and introduced the plasmid into an Escherichia coli strain already harboring a target plasmid. Mini-ISY100 transposed to the target plasmid in the presence of IPTG at a very high frequency. Mini-ISY100 was inserted into the TA sequence and duplicated it upon transposition, as do IS630 family elements. Moreover, the mini-ISY100-carrying plasmid produced linear molecules of mini-ISY100 with the exact 3' ends of ISY100 and 5' ends lacking two nucleotides of the ISY100 sequence. No bacterial insertion elements have been shown to generate such molecules, whereas the eukaryotic Tc1/mariner family elements, Tc1 and Tc3, which transpose to the TA sequence, have. These findings suggest that ISY100 transposes to a new site through the formation of linear molecules, such as Tc1 and Tc3, by excision. Some Tc1/mariner family elements leave a footprint with an extra sequence at the site of excision. No footprints, however, were detected in the case of ISY100, suggesting that eukaryotes have a system that repairs a double strand break at the site of excision by an end-joining reaction, in which the gap is filled with a sequence of several base pairs, whereas prokaryotes do not have such a system. ISY100 transposes in E. coli, indicating that it transposes without any host factor other than the transposase encoded by itself. Therefore, it may be able to transpose in other biological systems.

Identification of the region that determines the specificity of binding of the transposases encoded by Tn3 and gamma delta to the terminal inverted repeat sequences

To analyze the region that determines the specificity of binding of the Tn3 transposase to the terminal inverted repeat sequences (IR), we first determined the nucleotide sequence of a Tn3-family transposon, gamma delta, which is supposed to encode a transposase similar to that of Tn3. gamma delta was 5981 bp in length and contained three coding frames: Two were the genes, tnpA and tnpR, encoding transposase (1002 amino acids) and resolvase/repressor (183 amino acids), respectively, and the third, named tnpX, encoding a protein (698 amino acids) of unknown function but containing two NTP-binding motifs. Utilizing the tnpA sequence, we then constructed a series of Tn3-gamma delta hybrid genes encoding chimeric proteins in the N-terminal segments of the transposases (amino acid position 1 to 242 of Tn3 or 1' to 243' of gamma delta), which has been previously shown to be responsible for specific binding of transposase to IR sequences in Tn3. Examination of their DNA-binding activities revealed that the subsegment of the N-terminus from amino acid position 1 to 109 determines the specificity of binding to the IR sequences. The third coding frame found in gamma delta, tnpX, is located downstream of tnpR and is expressed from the tnpR promoter in the absence of the tnpR gene product, resolvase/repressor, to produce a protein that inhibits the growth of the host cells. Possible roles of this protein are discussed.

DNA binding domains in Tn3 transposase

Various segments of Tn3 transposase were fused individually to beta-galactosidase, and the resulting fusion proteins were examined for their DNA binding ability by a nitrocellulose filter binding assay. Analyses of a series of the fusion proteins revealed that the N-terminal segment of the transposase (amino acid positions 1-242; the transposase gene encodes 1004 residues in all) had specific DNA binding ability for the 38 bp terminal inverted repeat (IR) sequence, and the central segment (amino acid positions 243-632) had non-specific DNA binding ability. Further analyses of each of the two regions revealed that the N-terminal segment could be divided into at least two subsegments (amino acid positions 1-86 and 87-242), neither of which had specific DNA binding ability, but which both possessed non-specific DNA binding ability. The central segment included two subsegments (amino acid positions 243-289 and 439-505) with non-specific DNA binding ability. These results and other observations suggest that Tn3 transposase has several domains including those responsible for non-specific DNA binding, and a combination of two or more domains gives rise to specific DNA binding activity. The C-terminal segment of the transposase (amino acid positions 633-1004), which is very well conserved among transposases encoded by Tn3 family transposons, had no DNA binding ability. This segment may represent the main part of the catalytic domain responsible for the initiation step of transposition.

Functional analysis of the two domains in the terminal inverted repeat sequence required for transposition of Tn3

Bacterial transposon Tn3 has a 38-bp terminal inverted repeat (IR) sequence. The IR sequence has been divided into two domains, A and B, of which domain B is bound by transposase, and domain A is not Here, we defined the two domains more precisely by constructing three IR mutants with a 2-bp substitution at relevant sites within the IR sequence, followed by examination of the binding of transposase to the fragments containing these IR mutants: domain A was located at bp 1-11, whereas domain B was at bp 12-38. To see if the two domains in the IR are functionally distinct, we constructed mini-Tn3 derivatives flanked by two IRs with various 2-bp substitutions within domain A or B, and analyzed their ability to mediate cointegration. The mini-Tn3 derivatives flanked by IR(A+ B+) and IR(A- B+) [or IR(A+ B-)] and those flanked by IR(A-B+) and IR(A+ B-) mediate cointegration more efficiently than the mini-Tn3 derivatives flanked by two IR(A- B+)s or by two IR(A+ B-)s. These results and others presented here indicate that the two domains of IR are functionally distinct in promoting cointegration.

Identification, DNA sequence, and distribution of IS981, a new, high-copy-number insertion sequence in lactococci

An insertion in the lactococcal plasmid pGBK17, which inactivated the gene(s) encoding resistance to the prolate-headed phage c2, was cloned, sequenced, and identified as a new lactococcal insertion sequence (IS). IS981 was 1,222 bp in size and contained two open reading frames, one large enough to encode a transposase. IS981 ended in imperfect inverted repeats of 26 of 40 bp and generated a 5-bp direct repeat of target DNA at the site of insertion. IS981 was present on the chromosome of Lactococcus lactis subsp. lactis LM0230 from where it transposed to pGBK17 during transformation. Twenty-three strains of lactococci examined for the presence of IS981 by Southern hybridization showed 4 to 26 copies per genome, with L. lactis subsp. cremoris strains containing the highest number of copies. Comparison of the DNA sequence and the amino acid sequence of the long open reading frame to other known sequences showed that IS981 is related to a family of IS elements that includes IS2, IS3, IS51, IS150, IS600, IS629, IS861, IS904, and ISL1.

Tn3 transposition immunity is conferred by the transposase-binding domain in the terminal inverted-repeat sequence of Tn3

A series of mutant terminal inverted repeats (IRs), having 2 bp substitutions at various sites within the 38-bp IR sequence of the ampicillin-resistance transposon Tn3, were tested for transposition immunity to Tn3. Mutations within region 1-10 in the IR did not affect transposition immunity, while mutations within region 13-38 inactivated the immunity function. These two regions corresponded to domain A which was not bound specifically by Tn3 transposase and to domain B which was bound by the transposase, respectively. This indicates that specific binding of transposase to domain B within the IR sequence is responsible for transposition immunity.

Two domains in the terminal inverted-repeat sequence of transposon Tn3

Tn3 and related transposons have terminal inverted repeats (IR) of about 38 bp that are needed as sites for transposition. We made mini-Tn3 derivatives which had a wild-type IR of Tn3 at one end and either the divergent IR of the Tn3-related transposon, gamma delta or IS101, or a mutant IR of Tn3 at the other end. We then examined both in vivo transposition (cointegration between transposition donor and target molecules) of these mini-Tn3 elements and in vitro binding of Tn3-encoded transposase to their IRs. None of the elements with an IR of gamma delta or IS101 mediated cointegration efficiently. This was due to inefficient binding of transposase to these IR. Most mutant IR also interfered with cointegration, even though transposase bound to some mutant IR as efficiently as it did to wild type. This permitted the Tn3 IR sequence to be divided into two domains, named A and B, with respect to transposase binding. Domain B, at positions 13-38, was involved in transposase binding, whereas domain A, at positions 1-10, was not. The A domain may contain the sequence recognized by some other (e.g., host) factor(s) to precede the actual cointegration event.

Nucleotide sequences required for Tn3 transposition immunity

The Tn3 transposon inserts at a reduced frequency into a plasmid already containing a copy of Tn3, a phenomenon known as transposition immunity. The cis-acting site on Tn3 responsible for immunity was mapped by deletions from each side to be within the terminal 38-base-pair sequence that is inversely repeated at the ends of Tn3. Two palindromic sequences are present in the essential part of this region. Some deletions conferred only partial immunity, and others conferred negative immunity. Multiple copies of partially immune ends conferred additional immunity. No other part of Tn3 was necessary for immunity.

ISR1, a transposable DNA sequence resident in Rhizobium class IV strains, shows structural characteristics of classical insertion elements

ISR1 is a small transposable element, identified in Rhizobium class IV strains by its high frequent mutagenic insertion into plasmid RP4. Hybridization studies showed that ISR1 is present in, multiple copies in Rhizobium class IV strains. Nucleotide sequence analysis revealed that ISR1 has a length of 1260 bp and is characterized by perfect inverted repeats of 13 nucleotides followed by a stretch of 28/29 nucleotides with imperfect homology. The insertion under study generated a target site duplication of 4 bp. ISR1 carries a large open reading frame, encoding a putative polypeptide of 278 amino acids (ORFA*), and three smaller ones in antiparallel direction (ORFs A1, A2, A3). Two of them are completely covered by the large open reading frame. No significant homology to 17 other known insertion sequence elements could be detected, either at nucleotide or at amino acid levels.

Polymorphisms in the umuDC region of Escherichia species

The umuDC operon of Escherichia coli encodes mutagenic DNA repair. The umuDC regions of multiple isolates of E. coli, E. alkalescens, and E. dispar and a single stock of E. aurescens were mapped by nucleotide hybridization. umuDC is located at one end of a conserved tract of restriction endonuclease sites either 12.5 or 14 kilobase pairs long. Rearrangements, including possible deletions, were seen in the polymorphic DNA flanking the conserved tract. Restriction site polymorphisms were not found around the DNA repair gene recA or polA. The junctions of the conserved region contain direct repeats of nucleotide sequences resembling the termini of the Tn3 group of transposons. Possible mechanisms for the generation of these variants are discussed.

Monitoring for the development of antimicrobial resistance during the use of olaquindox as a feed additive on commercial pig farms

Since 1982, when olaquindox was introduced as a pig-feed additive in the UK, about 12 commercial farms in Suffolk have been monitored annually to check for the possible emergence of resistance to olaquindox and chloramphenicol among the coliform flora of the pigs and their environment. In spite of the sampling variability and the impossibility of controlling the use of feed additives and management on the farms, the overall results obtained were consistent and, it is suggested, the method is widely applicable. A steady, albeit low, increasing incidence and level of resistance to olaquindox was recorded (1982-1984) on farms using it and, to a lesser degree, on neighbouring farms that did not. No significant increase in the level of chloramphenicol resistance was observed. Genetical studies on a selection of olaquindox-resistant isolates suggested that the genes determining resistance were likely to be borne on the chromosome.

Specific binding of transposase to terminal inverted repeats of transposable element Tn3

Tn3 transposase, which is required for transposition of Tn3, has been purified by a low-ionic-strength-precipitation method. Using a nitrocellulose filter binding assay, we have shown that transposase binds to any restriction fragment. However, binding of the transposase to specific fragments containing the terminal inverted repeat sequences of Tn3 can be demonstrated by treatment of transposase-DNA complexes with heparin, which effectively removes the transposase bound to the other nonspecific fragments at pH 5-6. DNase I "footprinting" analysis showed that the transposase protects an inner 25-base-pair region of the 38-base-pair terminal inverted repeat sequence of Tn3. This protection is not dependent on pH. Interestingly, binding of the transposase to the inverted repeat sequences facilitates DNase I to nick at the end of the Tn3 sequence. It was also observed that the transposase protects the end regions of restriction fragments with a cohesive sequence at their 5' end or with a flush end from DNase I cleavage. The specific and nonspecific binding of transposase to DNA is ATP-independent.

Identification of a new insertion element, similar to gram-negative IS26, on the lactose plasmid of Streptococcus lactis ML3

In Streptococcus lactis ML3, the lactose plasmid (pSK08) forms cointegrates with a conjugal plasmid (pRS01). It has been proposed that cointegration is mediated by insertion sequences (IS) present on pSK08 (D. G. Anderson and L.L. McKay, J. Bacteriol. 158:954-962, 1984). We examined the junction regions of the cointegrate pPW2 and the corresponding regions of pSK08 (donor) and pRS01 (target) and identified a new IS element on pSK08 (ISS1S) which was involved in and duplicated during formation of pPW2. ISS1S was 808 base pairs (bp) in size, had 18-bp inverted repeats (GGTTCTGTTGCAAAGTTT) at its ends, contained a single long open reading frame encoding a putative protein of 226 amino acids, and generated 8-bp direct repeats of target DNA during cointegrate formation. An iso-IS element, ISS1T, which is duplicated in some other cointegrate plasmids, was also found on pSK08. ISS1T was also 808 bp in size and was identical to ISS1S in sequence except for 4 bp, none of which altered the inverted repeats or amino acid sequence of the open reading frame. Comparison of ISS1 with gram-negative IS26 revealed strong homologies in size (820 bp), sequence of inverted repeats (GGCACTGTTGCAAA), size of direct repeats generated after cointegration (8 bp), and number, size, and amino acid sequence (44.5% identical) of the open reading of frame.

Characteristics of the yellow pigment from a strain of Yersinia enterocolitica biovar 1

Yersinia enterocolitica 195A14J, a milk-isolated strain of biovar 1, produces a non-diffusible yellow pigment and forms star-shaped colonies when grown on egg-yolk agar at 28 degrees C. Solubility properties and in situ Raman spectrum of the pigment support evidence that it is not a carotenoid, although it contains a 9 (+/- 1) double-bond polyenic chain. Pigmentless variants, also star-shaped, appeared with a frequency of ca.10(-3) when bacteria were grown at 38 degrees C. Agarose gel electrophoresis of DNA extracted from the pigmented strain revealed the presence of a 42-kb plasmid which was lost in pigmentless variants.

Isolation and characterization of IS elements repeated in the bacterial chromosome

Shigella sonnei contains repetitive sequences, including an insertion element IS1, which can be isolated as double-stranded DNA fragments by DNA denaturation and renaturation and by treatment with S1 nuclease. In this paper, we describe a method of cloning the IS1 fragments prepared by the S1 nuclease digestion technique into phage M13mp8 RFI DNA. Several clones contained IS1, usually with a few additional bases. We isolated and characterized five other repetitive sequences using this method. One sequence, 1264 base-pairs in length, had terminal inverted repeats and contained two open reading frames. This sequence, called IS600, showed about 44% sequence homology with IS3 and was repeated more than 20 times in the Sh. sonnei chromosome. Another sequence (named IS629, 1310 base-pairs in length), which was repeated six times, was found also to be related to IS3 and thus IS600. Two other sequences (named IS630 and IS640, 1159 and 1092 base-pairs in length, respectively), which were repeated approximately ten times, had characteristic terminal inverted repeats and contained a large open reading frame coding for a protein. The inverted repeat sequences of IS630 were similar to the sequence at one end of IS200, a Salmonella-specific IS element. The fifth sequence, repeated ten times in Sh. sonnei, had about 98% sequence homology with a portion of IS2. The method described here can be applied to the isolation of IS or iso-IS elements present in any other bacterial chromosome.

Analysis of Tn3 sequences required for transposition and immunity

Tn3 is a 5-kb transposon (Tn) with 38-bp inverted terminal repeats (ITR). The two 38-bp terminal sequences are required in cis for Tn3 transposition. In this study, the role of the ITR in Tn3 transposition has been further dissected by the use of various mini-Tn3 Tn's. The transposition frequency of these mini-Tn's demonstrate that Tn3 contains no sequence other than the ITR sequences that are necessary for the first step in transposition; the two terminal repeats must be oriented as ITR for transposition to occur; the outside 34 bp of the ITR are required for transposition; and reducing the distance between the terminal sequences does not affect transposition frequency. Moreover, mutant copies of the ITR sequences that cannot function in transposition do not confer transposition immunity.

Cointegration and resolution mediated by IS101 present in plasmid pSC101

A certain class of cointegrate plasmids was found to occur between a pSC101 derivative and a second plasmid pBV320 in E. coli F- cells. Cleavage analysis and DNA sequencing showed that the cointegrate plasmid contained direct repeats of an insertion sequence IS101 at the recombination junctions, indicating that formation of cointegrates was mediated by IS101, which is a natural constituent of pSC101. These cointegrates were formed only in cells which contained the transposon gamma-delta, suggesting that the gamma-delta sequence, which provides transposase, is responsible for cointegration. Whenever the cointegrate plasmids were present in cells containing gamma-delta or its related transposon Tn3, the cointegrates were dissolved to give pBV320::IS101 due to recombination at duplicated IS101 sequences in the cointegrates, suggesting that both gamma-delta and Tn3, which provide a resolvase, are responsible for the resolution of the cointegrates. Comparison between the nucleotide sequence of IS101 and those of gamma-delta and Tn3 shows a high degree of homology in the regions that have been shown to be the binding sites of resolvases, as well as in the terminal inverted repeats. However, there is no homology between IS101 and the other element, gamma-delta or Tn3, in the internal resolution site, at which the resolution event may occur.

ATP-dependent specific binding of Tn3 transposase to Tn3 inverted repeats

Transposons are discrete segments of DNA which are capable of moving from one site in a genome to many different sites. Tn3 is a prokaryotic transposon which is 4,957 base pairs (bp) long and encodes a transposase protein which is essential for transposition. We report here a simple method for purifying Tn3 transposase and demonstrate that the transposase protein binds specifically to the ends of the Tn3 transposon in an ATP-dependent manner. The transposase protein binds to linear double-stranded DNA both nonspecifically and specifically; the nonspecific DNA binding activity is sensitive to challenge with heparin. Site-specific DNA binding to the ends (inverted repeats) of Tn3 is observed only when binding is performed in the presence of ATP; this ATP-dependent site-specific DNA binding activity is resistant to heparin challenge. Our results indicate that ATP qualitatively alters the DNA binding activity of the transposase protein so that the protein is able to bind specifically to the ends of the Tn3 transposon.

Cointegrates carrying two copies of a Tn3 derivative in an inverted orientation

We constructed a mutant of Tn3, Tn3 #2, that contains a 55-bp direct repeat of sequences near the amino-terminal coding region of the transposase, and an 8-bp EcoRI linker. This mutant transposase is functional. The plasmid carrying Tn3 #2, pMB8::Tn3 #2, recombines with the plasmid pHS1 at a frequency of 2.8 X 10(-7) recombinants per division cycle. This is similar to the recombination frequency of pHS1 and pMB8::Tn3+ (wild-type) which is 4.5 X 10(-6) recombinants per division cycle. One-third of the recombinants between pMB8::Tn3 #2 and pHS1 were approx. 22 kb in length. Restriction analysis and nucleotide sequencing showed that these large plasmids were Tn3 #2-mediated cointegrates formed by integration of pMB8::Tn3 #2 into pHS1. However, unlike Tn3 tnpR- -mediated cointegrates that contain direct repeats of the incoming element, Tn3 #2-mediated cointegrates carry two copies of Tn3 #2 in the form of inverted repeats. Like the tnpR- repeats, the Tn3 #2 repeats occur at both junctions between the parental plasmids, and are associated with a 5-bp direct duplication of the pHS1 target site. Furthermore, these recombinants contain a small deletion starting precisely at the end of Tn3 #2 and extending into pMB8 sequences. We propose a model for the generation of Tn3 #2-mediated cointegrates.

Characterization of Tn3926, a new mercury-resistance transposon from Yersinia enterocolitica

A new transposon coding for mercury resistance (HgR), Tn3926, has been found in a strain of Yersinia enterocolitica, YE138A14. The element has a size of 7.8 kb and transposes to conjugative plasmids belonging to different incompatibility groups. A restriction map has been established. DNA-DNA hybridization indicates that Tn3926 displays homology with both Tn501 and Tn21; the greatest homology is shown with the regions of these transposons that encode HgR. Weaker homology is observed between Tn3926 sequences and those regions of Tn501 and Tn21 that encode transposition functions. Complementation experiments indicate that the Tn3926 transposase mediates transposition of Tn21, albeit somewhat inefficiently, but not of Tn501, while the resolvase mediates resolution of transposition cointegrates formed via Tn21, Tn501, or Tn1721.

Detection and characterization of Tn2501, a transposon included within the lactose transposon Tn951

The DNA sequence spanning coordinates 9.9 to 16.4 kilobases of the lactose transposon Tn951 ( Cornelis et al., Mol. Gen. Genet. 160:215-224, 1978) constitutes a transposable element by itself. Unlike Tn951 ( Cornelis et al., Mol. Gen. Genet. 184:241-248, 1981), this element, called Tn2501 , transposes in the absence of any other transposon. Transposition of Tn2501 proceeds through transient cointegration and duplicates 5 base pairs of host DNA. Tn2501 is flanked by nearly perfect inverted repeats (44 of 48), related to the inverted repeats of Tn21 ( Zheng et al., Nucleic Acids Res. 9:6265-6278, 1982). Unlike Tn21 , Tn2501 does not confer mercury resistance.

A 37 X 10(3) molecular weight plasmid-encoded protein is required for replication and copy number control in the plasmid pSC101 and its temperature-sensitive derivative pHS1

Nucleotide sequences were determined for a region essential for autonomous replication and partitioning of pSC101, a plasmid whose replication is dependent on the Escherichia coli dnaA gene product. The essential replication region contains one long coding sequence, rep101 , for a protein composed of 316 amino acids, and a polypeptide approximately 37 X 10(3) Mr in size was identified as the rep101 gene product. rep101 is preceded by two inverted repeat sequences, three directly repeated sequences and a region of high A + T content containing a sequence similar to the E. coli oriC consensus sequence. Because the lesions in seven replication-deficient insertion mutants, four mutants with increased copy number and one temperature-sensitive replication mutant occur within rep101 , the rep101 gene product must control pSC101 replication and copy number. par, a region adjacent to the replication region, which functions in stable plasmid inheritance, contains several inverted repeat sequences.

Identification of a transposon Tn3 sequence required for transposition immunity

A plasmid containing transposon Tn3 is immune to further insertions of Tn3. This phenomenon works in cis and is referred to as transposition immunity. We have used the ability of Tn3 to form cointegrates between two plasmids to develop a quantitative assay to detect transposition immunity. Presence of Tn3 on both the plasmids reduces the cointegration frequency to less than 1/100 of parental. Using this assay, we have determined that (i) tnpR is not required for immunity, (ii) only the terminal 38 base pairs of Tn3 need be present to confer immunity, and (iii) other parts of Tn3 appear not to confer immunity.

Escherichia coli RNA polymerase binding sites and transcription initiation sites in the transposon Tn3

We have identified the Escherichia coli RNA polymerase-binding sites and the transcription initiation sites in the transposon Tn3. Results from nitrocellulose filter-binding assays indicate that there are two regions within Tn3 capable of forming stable binary complexes with RNA polymerase. The two regions are a 208-bp region containing the N-terminal coding sequence of the transposase (tnpA) and repressor (tnpR) genes, and a 332-bp region containing the N-terminal coding sequence for the beta-lactamase (bla) gene. DNase I footprint analysis of the 208-bp and 332-bp fragments further defined an extended region of protection, approx. 110 bp long, located between the transposase and repressor coding regions, and an 80-bp region of protection near the N-terminal coding sequence of the beta-lactamase gene. In vitro transcription studies with fragments containing these protected regions allowed us to determine the precise transcription initiation sites for the transposase, repressor, and beta-lactamase mRNAs. The transposase and repressor mRNAs are transcribed divergently and their transcription initiation sites are separated by 80 bp. The -35 homology regions for the transposase and repressor promoters are separated by 10 bp and the -10 homology region of the transposase promoter is coincident with the recombination site (res) for the site-specific recombinase activity (resolvase) of the repressor protein, which is required for resolution of Tn3 cointegrates. We discuss the significance of this complex divergently transcribed promoter region with respect to regulation of Tn3 transposition and we propose a model for coordinated regulation of the tnpA and tnpR genes. We also compare the Tn3 tnpA-tnpR intercistronic region with that of the closely related transposon gamma delta.

Repression of cointegration ability of insertion element IS1 by transcriptional readthrough from flanking regions

We describe a repression mechanism in which read-through messages transcribed from a gene into an IS1 sequence inhibit its ability to mediate plasmid cointegration. This mechanism was derived from the demonstration that removal of the promoter region of the chloramphenicol resistance gene in transposon Tn9, or introduction of a strong transcription terminator of phage T7 downstream of the chloramphenicol resistance gene, increases the cointegration ability of the downstream IS1 sequence when in a particular orientation. The cointegration ability of an IS1 sequence downstream of the chloramphenicol resistance gene but in an orientation opposite that of the above-mentioned IS1 sequence also can be repressed. Analysis of transcripts synthesized in vitro showed that the transcripts of the chloramphenicol resistance gene were read through into the IS1 sequence located downstream of the gene in either orientation. Repression of this type may be one mechanism that controls the rate of transposition of the IS1 element, which apparently does not encode a structural gene for repressor.

R46 encodes a site-specific recombination system interchangeable with the resolution function of TnA

Transposition of Tn4 onto the IncN plasmic R46 generates unstable DNA molecules. The R46::TnA recombinant plasmids undergo further DNA rearrangements which depend on the orientation in which the TnA element is inserted into the plasmid, and deletions and inversions of R46 and TnA sequences have been observed. Both types of rearrangement have the same specific endpoints, one within TnA and one located between the R46 coordinates, 36.0 and 37.0. The results are consistent with the operation of a recA-independent, site-specific recombination system utilizing, at least in part, the transposon cointegrate resolution system of TnA, together with R46-encoded functions. Data are presented that indicate that R46 encodes analogs of both the res site of TnA and its tnpR gene, although little homology between this element and the plasmid is apparent. Models for the TnA-induced generation of site-specific deletions and inversions upon transposition of TnA to R46 are presented.

Transposon Tn3-mediated replicon fusion

To investigate inter-replicon transposition of Tn3, we used the cosmid-phage lambda packaging system coupled with density gradient fractionation and isolated recombinant molecules of different sizes. Cosmids derived from ampicillin-resistance-transducing phage were classified into four groups: (1) cosmid-Tn3 donor cointegrates considered as Tn3 transposition intermediates, (2) similar cointegrates carrying deletions of one copy of Tn3 and of adjacent cosmid DNA sequences, (3) cosmids carrying a single Tn3 insertion, and (4) cosmids carrying two independent Tn3 insertions. Genetic and biochemical studies indicated that cosmids isolated from ampicillin-resistance transductants were derived from the authentic cosmid-Tn3 donor cointegrate intermediates.

A gene and its product required for transposition of resistance transposon Tn2603

Tn2603 is a multiple-resistance transposon encoding resistance to ampicillin, streptomycin, sulfonamide, and mercury and having a molecular size of 20 kilobase pairs, with 200-base-pair inverted repeats at both ends. The essential sites and functions of Tn2603 which are required for its transposition were determined through construction and characterization of various deletion mutants affecting the efficiency of transposition. Deletions were introduced in plasmid pMK1::Tn2603 by partial digestion with restriction endonuclease EcoRI in vitro. Analysis of deletion mutants showed that the inverted repeat segments at both ends of the trans-acting diffusible product(s) encoded in the right-hand side of the central portion were required for the transposition of Tn2603. An essential gene product was revealed as a protein having a molecular weight of 110,000 by analysis of polypeptides synthesized in Escherichia coli minicells. This protein was assumed to be the so-called transposase.

Insertion sites and the terminal nucleotide sequences of the Tn4 transposon

The nucleotide sequences at the ends of the Tn4 transposon (mercury spectinomycin and sulfonamide resistance) have been determined. They are inverted repeated sequences of 38 nucleotides with three mismatched base pairs. These sequences are strongly homologous with the terminal sequences of Tn501 (mercury resistance) but less so with those of Tn3 (ampicillin resistance). The Tn4 transposon generates pentanucleotide members (Tn3, Tn1000, Tn501, Tn551, IS2) with the exception of Tn1721 and bacteriophage Mu. Among the three Tn4 insertion sites examined here, two of them occurred near a nonanucleotide sequence in perfect homology with part of the terminal inverted-repeat sequence of Tn4 and the third insertion occurred near a sequence of partial homology to one end of Tn4. All three insertions were in the same orientation such that IRb is proximal to its homologous sequence on the recipient DNA.

Factors determining frequency of plasmid cointegration mediated by insertion sequence IS1

We demonstrate that mutants with deletions at either end of the insertion sequence IS1 lose the ability to mediate cointegration of two plasmids, whereas mutants with deletions or an insertion within IS1 can mediate cointegration at a reduced frequency. These results, together with the nucleotide sequence analysis of the IS1 mutants, indicate that the two ends of IS1 (insL and insR) and two genes (insA and insB) that are encoded by IS1 are required for cointegration. Using a plasmid carrying two copies of IS1, we found that the individual IS1s mediate cointegration at different characteristic frequencies, and that each of two parts of plasmid DNA segments flanked by the two IS1s is a transposon, mediating plasmid cointegration at a unique frequency. When one IS1 was replaced with a mutant IS1, the remaining wild-type IS1 complemented the cointegration ability of the mutant IS1 as well as a resulting mutant transposon that was then flanked by a wild-type IS1 and a mutant IS1. The efficiency of this complementation reflected the characteristic ability of an individual IS1 present on the plasmid to promote cointegration. The results suggest that the IS1-encoded proteins are produced in different amounts, depending on the location of IS1 in the plasmid, and that these amounts determine the efficiency of complementation of the cointegration ability of a mutant IS1 as well as a mutant transposon. However, the location of an individual IS1 itself can also determine the frequency of cointegration in the presence of a given amount of the IS1 proteins. On the basis of the observation that the cointegration ability of a mutant IS1 is less efficiently complemented than is the ability of a mutant transposon, we also suggest that the IS1-encoded proteins can function in trans, but act preferentially on the IS1 or transposon sequence from which they are produced in promoting cointegration.